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Published April 2021 | Accepted Version + Published
Journal Article Open

The β Pictoris b Hill sphere transit campaign. I. Photometric limits to dust and rings

Kenworthy, M. A. ORCID icon
Mellon, S. N.
Bailey, J. I. ORCID icon
Stuik, R. ORCID icon
Dorval, P.
Talens, G. J. J.
Crawford, S. R.
Mamajek, E. E. ORCID icon
Laginja, I. ORCID icon
Ireland, M. ORCID icon
Lomberg, B.
Kuhn, R. B.
Snellen, I. ORCID icon
Zwintz, K. ORCID icon
Kuschnig, R.
Kennedy, G. M. ORCID icon
Abe, L.
Agabi, A.
Mekarnia, D.
Guillot, T. ORCID icon
Schmider, F.
Stee, P. ORCID icon
de Pra, Y. ORCID icon
Buttu, M.
Crouzet, N.
Kalas, P. ORCID icon
Wang, J. J. ORCID icon
Stevenson, K. ORCID icon
de Mooij, E. ORCID icon
Lagrange, A.-M. ORCID icon
Lacour, S. ORCID icon
Lecavelier des Etangs, A. ORCID icon
Nowak, M. ORCID icon
Strøm, P. A. ORCID icon
Hui, Z.
Wang, L.

Abstract

Aims. Photometric monitoring of β Pic in 1981 showed anomalous fluctuations of up to 4% over several days, consistent with foreground material transiting the stellar disk. The subsequent discovery of the gas giant planet β Pic b and the predicted transit of its Hill sphere to within a 0.1 au projected separation of the planet provided an opportunity to search for the transit of a circumplanetary disk (CPD) in this 21 ± 4 Myr-old planetary system. We aim to detect, or put an upper limit on, the density and nature of the material in the circumplanetary environment of the planet via the continuous photometric monitoring of the Hill sphere transit that occurred in 2017 and 2018. Methods. Continuous broadband photometric monitoring of β Pic requires ground-based observatories at multiple longitudes to provide redundancy and to provide triggers for rapid spectroscopic follow-up. These include the dedicated β Pic monitoring bRing observatories in Sutherland and Siding Springs, the ASTEP400 telescope at Concordia, and the space observatories BRITE and the Hubble Space Telescope (HST). We search the combined light curves for evidence of short-period transient events caused by rings as well as for longer-term photometric variability due to diffuse circumplanetary material. Results. We find no photometric event that matches with the event seen in November 1981, and there is no systematic photometric dimming of the star as a function of the Hill sphere radius. Conclusions. We conclude that the 1981 event was not caused by the transit of a CPD around β Pic b. The upper limit on the long-term variability of β Pic places an upper limit of 1.8 × 10²² g of dust within the Hill sphere (comparable to the ~100 km radius asteroid 16 Psyche). Circumplanetary material is either condensed into a disk that does not transit β Pic, condensed into a disk with moons that has an obliquity that does not intersect with the path of β Pic behind the Hill sphere, or is below our detection threshold. This is the first time that a dedicated international campaign has mapped the Hill sphere transit of an extrasolar gas giant planet at 10 au.

Additional Information

© ESO 2021. Article published by EDP Sciences. Received 4 December 2020; Accepted 8 February 2021; Published online 07 April 2021. We thank the referee for taking the time to review our paper, especially after the difficulties and disruptions of the past year. M.A.K. acknowledges funding from NOVA and Leiden Observatory for the bRing observatory at SAAO, and to the NSF/NWO for travel funding (NWO grant 629.003.025). J.W. is supported by the 51 Pegasi b Fellowship. GMK is supported by the Royal Society as a Royal Society University Research Fellow. M.A.K. thanks the staff and observatory support crews at the South African Astronomical Observatory in Sutherland for all the work they put in to make bRing a successful observing station, and which allowed us to obtain first light within the first week of installation. Part of this research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration (80NM0018D0004). Construction of the bRing observatory sited at Siding Springs, Australia was made possible with a University of Rochester University Research Award, help from Mike Culver and Rich Sarkis (UR), and generous donations of time, services, and materials from Joe and Debbie Bonvissuto of Freight Expediters, Michael Akkaoui and his team at Tanury Industries, Robert Harris and Michael Fay at BCI, Koch Division, Mark Paup, Dave Mellon, and Ray Miller and the Zippo Tool Room. The results reported herein benefitted from collaborations and/or information exchange within NASA's Nexus for Exoplanet System Science (NExSS) research coordination network sponsored by NASA's Science Mission Directorate. This research is based on observations made with the NASA/ESA Hubble Space Telescope obtained from the Space Telescope Science Institute, which is operated by the Association of Universities for Research in Astronomy, Inc., under NASA contract NAS 5–26555. These observations are associated with programs 14621 and 15119. ASTEP benefited from the support of the French and Italian polar agencies IPEV and PNRA in the framework of the Concordia station program and of Idex UCAJEDI (ANR-15-IDEX-01). This research made use of Astropy6, a community-developed core Python package for Astronomy (Astropy Collaboration 2013, 2018), Python (Van Rossum & Drake Jr 1995; Oliphant 2007), Matplotlib (Hunter 2007; Caswell et al. 2020), numpy (Oliphant 2006; Van Der Walt et al. 2011) and SciPy (Virtanen et al. 2020b,a).

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Additional details

Identifiers Related works Funding Dates
Created:
August 20, 2023
Modified:
October 23, 2023